// Copyright (C) 1985-1998 by Symantec
// Copyright (C) 2000-2009 by Digital Mars
// All Rights Reserved
// http://www.digitalmars.com
// Written by Walter Bright
/*
 * This source file is made available for personal use
 * only. The license is in /dmd/src/dmd/backendlicense.txt
 * For any other uses, please contact Digital Mars.
 */

/* Routines to handle elems.			*/

#if !SPP

#include	<stdio.h>
#include	<string.h>
#include	<time.h>
#include	<stdarg.h>

#if DDRT
#include 	"paccfp.h"
#endif

#include	"cc.h"
#include	"type.h"
#include	"el.h"
#include	"../l_service/c_ds/list.h"
#include	"../l_service/c_ds/mem.h"
#include	"oper.h"
#include	"type.h"

#include	"parser.h"
#include	"code.h"

#include	"global.h"
#include	"go.h"
#if TARGET_MAC
#include	"TG.h"
#endif

#if __POWERPC && TARGET_68K
#undef DDRT
#define DDRT 1		// turn ddrt on
#endif

static char __file__[] = __FILE__;	/* for tassert.h		*/
#include	"tassert.h"

#ifdef STATS
static int elfreed = 0;			/* number of freed elems	*/
static int eprm_cnt;			/* max # of allocs at any point	*/
#endif

#if TARGET_POWERPC
#include "cgobjxcoff.h"
#include "xcoff.h"
#endif

/*******************************
 * Do our own storage allocation of elems.
 */

static elem *nextfree = NULL;		/* pointer to next free elem	*/

static int elcount = 0;			/* number of allocated elems	*/
static int elem_size = sizeof(elem);

#ifdef DEBUG
static int elmax;			/* max # of allocs at any point	*/
#endif

/////////////////////////////
// Table to gather redundant strings in.

static struct STAB
{   symbol *sym;	// symbol that refers to the string
    char *p;		// pointer to the string
    int len;		// length of string p
} stable[16];
static int stable_si;

/************************
 * Initialize el package.
 */

void el_init()
{
    if (!configv.addlinenumbers)
	elem_size = sizeof(elem) - sizeof(Srcpos);
}

/*******************************
 * Initialize for another run through.
 */

void el_reset()
{
    stable_si = 0;
    for (int i = 0; i < arraysize(stable); i++)
	mem_free(stable[i].p);
    memset(stable,0,sizeof(stable));
}

#if TX86
/************************
 * Terminate el package.
 */

void el_term()
{
#if TERMCODE
	int i;

	for (i = 0; i < arraysize(stable); i++)
	    mem_free(stable[i].p);

#ifdef DEBUG
	dbg_printf("Max # of elems = %d\n",elmax);
#endif
	if (elcount != 0)
	    dbg_printf("unfreed elems = %d\n",elcount);
	while (nextfree)
	{   elem *e;

	    e = nextfree->E1;
#if TX86
	    mem_ffree(nextfree);
#else
	    MEM_PH_FREE(nextfree);
#endif
	    nextfree = e;
	}
#else
	assert(elcount == 0);
#endif
}
#endif

/***********************
 * Allocate an element.
 */

#if SCPP && __SC__ && __INTSIZE == 4 && TX86 && !_DEBUG_TRACE && !MEM_DEBUG && _WIN32 && !defined(DEBUG)

__declspec(naked) elem *el_calloc()
{
    __asm
    {
	mov	EAX,elcount
	push	EDI

	inc	EAX
	mov	EDI,nextfree

	test	EDI,EDI
	je	L27

	mov	EDX,E1[EDI]
	mov	elcount,EAX

	xor	EAX,EAX
	mov	nextfree,EDX
	jmp	L30

L27:	push	sizeof(elem)
	mov	elcount,EAX
	call	mem_fmalloc
	mov	EDI,EAX
	xor	EAX,EAX

L30:	mov	EDX,EDI
	mov	ECX,(sizeof(elem) + 3) / 4
    #if DOS386
	push	DS
	pop	ES
    #endif
	rep	stosd
	mov	EAX,EDX
	pop	EDI
	ret
    }
}

#else

elem *el_calloc()
{
    elem *e;
    static elem ezero;

    elcount++;
    if (nextfree)
    {	e = nextfree;
	nextfree = e->E1;
    }
    else
#if TX86
	e = (elem *) mem_fmalloc(sizeof(elem));
#else
	e = (elem *) MEM_PH_MALLOC(sizeof(elem));
#endif
#ifdef STATS
    eprm_cnt++;
#endif
    *e = ezero;				/* clear it		*/

#ifdef DEBUG
    e->id = IDelem;
    if (elcount > elmax)
	elmax = elcount;
#endif
    /*dbg_printf("el_calloc() = %p\n",e);*/
    return e;
}

#endif

/***************
 * Free element
 */

void el_free(elem *e)
{
    int op;
    tym_t ty;

L1:
    if (!e) return;
    elem_debug(e);
    //dbg_printf("el_free(%p)\n",e);
    //elem_print(e);
    if (SCPP && PARSER)
    {
	ty = e->ET ? e->ET->Tty : 0;
	type_free(e->ET);
    }
    else if (e->Ecount--)
	return;				// usage count
    elcount--;
    op = e->Eoper;
    switch (op)
    {
	case OPconst:
#if FLOATS_IN_CODE
	    if (!PARSER && FLT_CODESEG_CELEM(e))
	    	flt_free_elem(e);
#endif
	    break;

	case OPvar:
	    break;
	case OPrelconst:
#if SCPP
	    if (0 && PARSER && tybasic(ty) == TYmemptr)
		el_free(e->EV.sm.ethis);
#endif
	    break;
	case OPstring:
	case OPasm:
#if HOST_MPW
	    if ( !(e->Eflags&EFsmasm) )
#endif
#if TX86 || HOST_MPW
		// never free; it's alloc'd from temp mem in most (all?) cases
	    MEM_PH_FREE(e->EV.ss.Vstring);
#endif
	    break;
	default:
	    debug_assert(op < OPMAX);
	    if (!OTleaf(op))
	    {	elem *en;

		if (OTbinary(op))
		    el_free(e->E2);
		en = e->E1;
#ifdef DEBUG
		memset(e,0xFF,elem_size);
#endif
		e->E1 = nextfree;
		nextfree = e;

#ifdef STATS
		elfreed++;
#endif
		e = en;
		goto L1;
	    }
	    break;
    }
#ifdef DEBUG
  memset(e,0xFF,elem_size);
#endif
  e->E1 = nextfree;
  nextfree = e;

#ifdef STATS
  elfreed++;
#endif
}

#ifdef STATS
/* count number of elems available on free list */
void el_count_free()
    {
    elem *e;
    int count;
    
    for(e=nextfree;e;e=e->E1)
        count++;
    dbg_printf("Requests for elems %d\n",elcount);
    dbg_printf("Requests to free elems %d\n",elfreed);
    dbg_printf("Number of elems %d\n",eprm_cnt);
    dbg_printf("Number of elems currently on free list %d\n",count);
    }
#endif

/*********************
 * Combine e1 and e2 with a comma-expression.
 * Be careful about either or both being NULL.
 */

elem * el_combine(elem *e1,elem *e2)
{
    if (e1)
    {	if (e2)
	    e1 = (SCPP && PARSER) ? el_bint(OPcomma,e2->ET,e1,e2)
			: el_bin(OPcomma,e2->Ety,e1,e2);
    }
    else
	e1 = e2;
    return e1;
}

/*********************
 * Combine e1 and e2 as parameters to a function.
 * Be careful about either or both being NULL.
 */

elem * el_param(elem *e1,elem *e2)
{
    //printf("el_param(%p, %p)\n", e1, e2);
#if 0
    if (e2 && e2->Eoper != OPstrpar && tybasic(e2->Ety) == TYstruct)
	*(char*)0=0;
#endif
    if (e1)
    {	if (e2)
	    e1 = (SCPP && PARSER) ? el_bint(OPparam,tsvoid,e1,e2)
			: el_bin(OPparam,TYvoid,e1,e2);
    }
    else
	e1 = e2;
    return e1;
}

/*********************************
 * Create parameter list, terminated by a NULL.
 */

elem *el_params(elem *e1, ...)
{
    elem *e;
    va_list ap;

    e = NULL;
    for (va_start(ap, e1); e1; e1 = va_arg(ap, elem *))
    {
	e = el_param(e, e1);
    }
    va_end(ap);
    return e;
}

/*************************************
 * Create a quad word out of two dwords.
 */

elem *el_pair(tym_t tym, elem *lo, elem *hi)
{
#if 0
    lo = el_una(OPu32_64, TYullong, lo);
    hi = el_una(OPu32_64, TYullong, hi);
    hi = el_bin(OPshl, TYullong, hi, el_long(TYint, 32));
    return el_bin(OPor, tym, lo, hi);
#else
    return el_bin(OPpair, tym, lo, hi);
#endif
}


/*************************
 * Copy an element (not the tree!).
 */

void el_copy(elem *to,elem *from)
{
  assert(to && from);
  elem_debug(from);
  elem_debug(to);
  memcpy(to,from,elem_size);
  elem_debug(to);
}

/***********************************
 * Allocate a temporary, and return temporary elem.
 */

elem * el_alloctmp(tym_t ty)
{
  symbol *s;

  assert(MARS || !PARSER);
  s = symbol_generate(SCtmp,type_fake(ty));
  symbol_add(s);
  s->Sfl = FLtmp;
  s->Sflags = SFLfree | SFLunambig | GTregcand;
  return el_var(s);
}

/********************************
 * Select the e1 child of e.
 */

elem * el_selecte1(elem *e)
{   elem *e1;

    assert(!PARSER);
    elem_debug(e);
    assert(EOP(e));
    e1 = e->E1;
    elem_debug(e1);
    if (e->E2) elem_debug(e->E2);
    e->E1 = NULL;				// so e1 won't be freed
    if (configv.addlinenumbers)
    {
	if (e->Esrcpos.Slinnum)
	    e1->Esrcpos = e->Esrcpos;
    }
    e1->Ety = e->Ety;
//    if (tyaggregate(e1->Ety))
//	e1->Enumbytes = e->Enumbytes;
#if MARS
    if (!e1->Ejty)
	e1->Ejty = e->Ejty;
#endif
    el_free(e);
    return e1;
}

/********************************
 * Select the e2 child of e.
 */

elem * el_selecte2(elem *e)
{   elem *e2;

    //dbg_printf("el_selecte2(%p)\n",e);
    elem_debug(e);
    assert(EBIN(e));
    if (e->E1)
	elem_debug(e->E1);
    e2 = e->E2;
    elem_debug(e2);
    e->E2 = NULL;			// so e2 won't be freed
    if (configv.addlinenumbers)
    {
	if (e->Esrcpos.Slinnum)
	    e2->Esrcpos = e->Esrcpos;
    }
#if !(TARGET_MAC)
    if (PARSER)
	el_settype(e2,e->ET);
    else
    {	e2->Ety = e->Ety;
//	if (tyaggregate(e->Ety))
//	    e2->Enumbytes = e->Enumbytes;
    }
#endif
    el_free(e);
    return e2;
}

/*************************
 * Create and return a duplicate of e, including its leaves.
 * No CSEs.
 */

elem * el_copytree(elem *e)
{   elem *d;

    if (!e)
	return e;
    elem_debug(e);
    d = el_calloc();
    el_copy(d,e);
    assert(!e->Ecount);
    if (SCPP && PARSER)
    {
	type_debug(d->ET);
	d->ET->Tcount++;
    }
    if (EOP(e))
    {	d->E1 = el_copytree(e->E1);
	if (EBIN(e))
		d->E2 = el_copytree(e->E2);
    }
    else
    {
	switch (e->Eoper)
	{   case OPstring:
#if 0
		if (OPTIMIZER)
		{
		    /* Convert the string to a static symbol and
		       then just refer to it, because two OPstrings can't
		       refer to the same string.
		     */

		    el_convstring(e);	// convert string to symbol
		    d->Eoper = OPrelconst;
		    d->EV.sp.Vsym = e->EV.sp.Vsym;
		    break;
		}
#endif
#if 0
	    case OPrelconst:
		e->EV.sm.ethis = NULL;
		break;
#endif
#if TX86
	    case OPasm:
		d->EV.ss.Vstring = (char *) mem_malloc(d->EV.ss.Vstrlen);
		memcpy(d->EV.ss.Vstring,e->EV.ss.Vstring,e->EV.ss.Vstrlen);
		break;
#else
	    case OPasm:
		if (e->Eflags&EFsmasm)
		{
		    d->Eflags |= EFsmasm;
		    d->EV.mac.Vasmdat[0] = e->EV.mac.Vasmdat[0];
		    d->EV.mac.Vasmdat[1] = e->EV.mac.Vasmdat[1];
		}
	 	else 
		{	
		    debug_assert(PARSER);
		    d->EV.ss.Vstring = (char *)MEM_PH_MALLOC(d->EV.ss.Vstrlen);
		    memcpy(d->EV.ss.Vstring,e->EV.ss.Vstring,e->EV.ss.Vstrlen);
		}
		break;
#endif
	}
    }
    return d;
}

/*************************
 * Similar to el_copytree(e). But if e has any side effects, it's replaced
 * with (tmp = e) and tmp is returned.
 */

elem * el_same(elem **pe)
{   elem *e = *pe;

    if (e && el_sideeffect(e))
    {
	*pe = exp2_copytotemp(e);	/* convert to ((tmp=e),tmp)	*/
	e = (*pe)->E2;			/* point at tmp			*/
    }
    return el_copytree(e);
}

/**************************
 * Replace symbol s1 with s2 in tree.
 */

#if SCPP

void el_replace_sym(elem *e,symbol *s1,symbol *s2)
{
    symbol_debug(s1);
    symbol_debug(s2);
    while (1)
    {	elem_debug(e);
	if (EOP(e))
	{   if (EBIN(e))
		el_replace_sym(e->E2,s1,s2);
	    e = e->E1;
	}
	else
	{
	    switch (e->Eoper)
	    {
		case OPvar:
		case OPrelconst:
		    if (e->EV.sp.Vsym == s1)
			e->EV.sp.Vsym = s2;
		    break;
	    }
	    break;
	}
    }
}

#endif

/*************************************
 * Does symbol s appear in tree e?
 * Returns:
 *	1	yes
 *	0	no
 */

#if MARS

int el_appears(elem *e,Symbol *s)
{
    symbol_debug(s);
    while (1)
    {	elem_debug(e);
	if (EOP(e))
	{   if (EBIN(e) && el_appears(e->E2,s))
		return 1;
	    e = e->E1;
	}
	else
	{
	    switch (e->Eoper)
	    {
		case OPvar:
		case OPrelconst:
		    if (e->EV.sp.Vsym == s)
			return 1;
		    break;
	    }
	    break;
	}
    }
    return 0;
}

/*****************************************
 * Look for symbol that is a base of addressing mode e.
 * Returns:
 *	s	symbol used as base
 * 	NULL	couldn't find a base symbol
 */

#if 0
Symbol *el_basesym(elem *e)
{   Symbol *s;

    s = NULL;
    while (1)
    {	elem_debug(e);
	switch (e->Eoper)
	{
	    case OPvar:
		s = e->EV.sp.Vsym;
		break;
	    case OPcomma:
		e = e->E2;
		continue;
	    case OPind:
		s = el_basesym(e->E1);
		break;
	    case OPadd:
		s = el_basesym(e->E1);
		if (!s)
		    s = el_basesym(e->E2);
		break;
	}
	break;
    }
    return s;
}
#endif

/****************************************
 * Does any definition of lvalue ed appear in e?
 * Returns:
 *	1	yes
 *	0	no
 */

int el_anydef(elem *ed, elem *e)
{   int op;
    int edop;
    Symbol *s;
    elem *e1;

    edop = ed->Eoper;
    s = (edop == OPvar) ? ed->EV.sp.Vsym : NULL;
    while (1)
    {
	op = e->Eoper;
	if (!OTleaf(op))
	{
	    e1 = e->E1;
	    if (OTdef(op))
	    {
		if (e1->Eoper == OPvar && e1->EV.sp.Vsym == s)
		    return 1;

		// This doesn't cover all the cases
		if (e1->Eoper == edop && el_match(e1,ed))
		    return 1;
	    }
	    if (OTbinary(op) && el_anydef(ed,e->E2))
		return 1;
	    e = e1;
	}
	else
	    break;
    }
    return 0;
}

#endif

/************************
 * Make a binary operator node.
 */

elem * el_bint(unsigned op,type *t,elem *e1,elem *e2)
{   elem *e;

    /* e2 is NULL when OPpostinc is built	*/
    assert(op < OPMAX && OTbinary(op) && e1);
    assert(PARSER);
    e = el_calloc();
    if (t)
    {	e->ET = t;
	type_debug(t);
	e->ET->Tcount++;
    }
    e->Eoper = op;
    elem_debug(e1);
    if (e2)
	elem_debug(e2);
    e->E1 = e1;
    e->E2 = e2;
    return e;
}

elem * el_bin(unsigned op,tym_t ty,elem *e1,elem *e2)
{   elem *e;

#ifdef DEBUG
    if (!(op < OPMAX && OTbinary(op) && e1 && e2))
	*(char *)0 = 0;
#endif
    assert(op < OPMAX && OTbinary(op) && e1 && e2);
    assert(MARS || !PARSER);
    elem_debug(e1);
    elem_debug(e2);
    e = el_calloc();
    e->Ety = ty;
    e->Eoper = op;
    e->E1 = e1;
    e->E2 = e2;
    if (op == OPcomma && tyaggregate(ty))
	e->Enumbytes = e2->Enumbytes;
    return e;
}

/************************
 * Make a unary operator node.
 */

elem * el_unat(unsigned op,type *t,elem *e1)
{   elem *e;

#ifdef DEBUG
    if (!(op < OPMAX && OTunary(op) && e1))
	dbg_printf("op = x%x, e1 = %p\n",op,e1);
#endif
    assert(op < OPMAX && OTunary(op) && e1);
    assert(PARSER);
    elem_debug(e1);
    e = el_calloc();
    e->Eoper = op;
    e->E1 = e1;
    if (t)
    {
	type_debug(t);
	t->Tcount++;
	e->ET = t;
    }
    return e;
}

elem * el_una(unsigned op,tym_t ty,elem *e1)
{   elem *e;

#ifdef DEBUG
    if (!(op < OPMAX && OTunary(op) && e1))
	dbg_printf("op = x%x, e1 = %p\n",op,e1);
#endif
    assert(op < OPMAX && OTunary(op) && e1);
    assert(MARS || !PARSER);
    elem_debug(e1);
    e = el_calloc();
    e->Ety = ty;
    e->Eoper = op;
    e->E1 = e1;
    return e;
}

/*******************
 * Make a constant node out of integral type.
 */

elem * el_longt(type *t,targ_llong val)
{ elem *e;

  assert(PARSER);
  e = el_calloc();
  e->Eoper = OPconst;
  e->ET = t;
  if (e->ET)
  {	type_debug(t);
	e->ET->Tcount++;
  }
  e->EV.Vllong = val;
  return e;
}

elem * el_long(tym_t t,targ_llong val)
{ elem *e;

  assert(MARS || !PARSER);
  e = el_calloc();
  e->Eoper = OPconst;
  e->Ety = t;
  switch (tybasic(t))
  {
	case TYfloat:
	case TYifloat:
	    e->EV.Vfloat = val;
	    break;
	case TYdouble:
	case TYidouble:
	    e->EV.Vdouble = val;
	    break;
	case TYldouble:
	case TYildouble:
	    e->EV.Vldouble = val;
	    break;
	case TYcfloat:
	case TYcdouble:
	case TYcldouble:
	    assert(0);
	    break;
	default:
	    e->EV.Vllong = val;
	    break;
  }
  return e;
}

/*******************************
 * If elem is a const that can be converted to an OPconst,
 * do the conversion.
 */

#if SCPP
void el_toconst(elem *e)
{
    elem_debug(e);
    assert(PARSER);
#if TX86
    if (e->Eoper == OPvar && e->EV.sp.Vsym->Sflags & SFLvalue)
#else
    if (e->Eoper == OPvar && e->EV.sp.Vsym->Sflags & SFLvalue &&
    	tybasic(e->ET->Tty) != TYstruct)
#endif
    {	elem *es = e->EV.sp.Vsym->Svalue;

	type_debug(e->ET);
	symbol_debug(e->EV.sp.Vsym);
	elem_debug(es);
	e->Eoper = es->Eoper;
	assert(e->Eoper == OPconst);
#if TARGET_MAC
#if !DDRT
        if (tyfloating(tybasic(es->ET->Tty)))
        {
	    long double ld;
        
	    switch (tysize[tybasic(es->ET->Tty)])
            {
            case FLOATSIZE:         	// TYfloat
                ld = es->EV.Vfloat;
       		break;
	    case DOUBLESIZE:         	// TYdouble
		ld = es->EV.Vdouble;
		break;
            case LNGDBLSIZE:        	// TYldouble
#ifdef LNGHDBLSIZE
	    case LNGHDBLSIZE:
#endif
#if (TARGET_POWERPC)
	    	if (config.flags & CFGldblisdbl)
		    ld = es->EV.Vdouble;
		else
#endif
		    ld = es->EV.Vldouble;
		break;
            default:
		assert(0);
            }
        
	    switch(tysize[tybasic(e->ET->Tty)])
            {
            case FLOATSIZE:         	// TYfloat
		e->EV.Vfloat = ld;
		break;
            case DOUBLESIZE:         	// TYdouble
		e->EV.Vdouble = ld;
		break;
            case LNGDBLSIZE:        	// TYldouble
#ifdef LNGHDBLSIZE
	    case LNGHDBLSIZE:
#endif
#if (TARGET_POWERPC)
		if (config.flags & CFGldblisdbl)
		    e->EV.Vdouble = ld;
		else
#endif
		    e->EV.Vldouble = ld;
		break;
            default:
		assert(0);
            }
        }
#else /* DDRT */
	if (tyfloating(tybasic(es->ET->Tty)))
        {
	    _extended_ ld;
        
	    switch (tysize[tybasic(es->ET->Tty)])
            {
            case FLOATSIZE:         	// TYfloat
		ld = Xftox(es->EV.Vfloat);
		break;
	    case DOUBLESIZE:         	// TYdouble
		ld = Xdtox(es->EV.Vdouble);
		break;
            case LNGDBLSIZE:        	// TYldouble
#ifdef LNGHDBLSIZE
	    case LNGHDBLSIZE:
#endif
#if TARGET_POWERPC
		if (config.flags & CFGldblisdbl)
		    ld = Xdtox(es->EV.Vdouble);
		else
#endif
		    ld = es->EV.Vldouble;
		break;
            default:
		assert(0);
            }
        
            switch(tysize[tybasic(e->ET->Tty)])
            {
            case FLOATSIZE:         	// TYfloat
		e->EV.Vfloat = Xxtof(ld);
		break;
            case DOUBLESIZE:         	// TYdouble
		e->EV.Vdouble = Xxtod(ld);
		break;
            case LNGDBLSIZE:        	// TYldouble
#ifdef LNGHDBLSIZE
	    case LNGHDBLSIZE:
#endif
#if TARGET_POWERPC
	    	if (config.flags & CFGldblisdbl)
		    e->EV.Vdouble = Xxtod(ld);
		else
#endif
		    e->EV.Vldouble = ld;
		break;
            default:
		assert(0);
            }
        }
#endif /* DDRT */
        else
#endif
	{
	    e->EV = es->EV;
	}
    }
}
#endif

/*******************************
 * Set new type for elem.
 */

elem * el_settype(elem *e,type *t)
{
#if MARS
    assert(0);
#else
    assert(PARSER);
    elem_debug(e);
    type_debug(t);
    type_settype(&e->ET,t);
#endif
    return e;
}

/*******************************
 * Walk tree, replacing symbol s1 with s2.
 */

#if SCPP

void el_replacesym(elem *e,symbol *s1,symbol *s2)
{
    _chkstack();

    assert(PARSER);
    while (e)
    {	elem_debug(e);
	if (EOP(e))
	{   el_replacesym(e->E2,s1,s2);
	    e = e->E1;
	}
	else
	{
	    if ((e->Eoper == OPvar || e->Eoper == OPrelconst) &&
		e->EV.sp.Vsym == s1)
		e->EV.sp.Vsym = s2;
	    break;
	}
    }
}

#endif

/*******************************
 * Create elem that is the size of a type.
 */

elem * el_typesize(type *t)
{
#if MARS
    assert(0);
    return NULL;
#else
    assert(PARSER);
    type_debug(t);
    if (CPP && tybasic(t->Tty) == TYstruct && t->Tflags & TFsizeunknown)
    {	elem *e;

	symbol_debug(t->Ttag);
	e = el_calloc();
	e->Eoper = OPsizeof;
	e->EV.sp.Vsym = t->Ttag;
	e->ET = tssize;
	e->ET->Tcount++;
	type_debug(tssize);
	elem_debug(e);
	return e;
    }
    else if (tybasic(t->Tty) == TYarray && type_isvla(t))
    {
	type *troot = type_arrayroot(t);
	elem *en;

	en = el_nelems(t);
	return el_bint(OPmul, en->ET, en, el_typesize(troot));
    }
    else
	return el_longt(tssize,type_size(t));
#endif
}

/*****************************
 * Return an elem that evaluates to the number of elems in a type
 * (if it is an array). Returns NULL if t is not an array.
 */

#if SCPP
elem * el_nelems(type *t)
{   elem *enelems;

    assert(PARSER);
    type_debug(t);
    if (tybasic(t->Tty) == TYarray)
    {	type *ts = tssize;

	enelems = el_longt(ts, 1);
	do
	{
	    if (t->Tflags & TFsizeunknown ||
		(t->Tflags & TFvla && !t->Tel))
	    {	synerr(EM_unknown_size,"array");	// size of array is unknown
		t->Tflags &= ~TFsizeunknown;
	    }
	    else if (t->Tflags & TFvla)
	    {
		enelems = el_bint(OPmul, ts, enelems, el_copytree(t->Tel));
	    }
	    else if (enelems->Eoper == OPconst)
	    {   enelems->EV.Vllong *= t->Tdim;
		type_chksize(enelems->EV.Vllong);
	    }
	    else
		enelems = el_bint(OPmul, enelems->ET, enelems, el_longt(ts, t->Tdim));
	    t = t->Tnext;
	} while (tybasic(t->Tty) == TYarray);
    }
    else
	enelems = NULL;
    return enelems;
}
#endif

/************************************
 * Return != 0 if function has any side effects.
 */

#if MARS

int el_funcsideeff(elem *e)
{   Symbol *s;

    if (e->Eoper == OPvar &&
	tyfunc((s = e->EV.sp.Vsym)->Stype->Tty) &&
	((s->Sfunc && s->Sfunc->Fflags3 & Fnosideeff) || s == funcsym_p)
       )
	return 0;
    return 1;			// assume it does have side effects
}

#endif

/****************************
 * Return != 0 if elem has any side effects.
 */

int el_sideeffect(elem *e)
{	int op;

	assert(e);
	op = e->Eoper;
	assert(op < OPMAX);
	elem_debug(e);
	return	typemask(e) & mTYvolatile ||
		OTsideff(op) ||
		(OTunary(op) && el_sideeffect(e->E1)) ||
		(OTbinary(op) && (el_sideeffect(e->E1) ||
				      el_sideeffect(e->E2)));
}

#if TX86
/******************************
 * Input:
 *	ea	lvalue (might be an OPbit)
 * Returns:
 *	0	eb has no dependency on ea
 *	1	eb might have a dependency on ea
 *	2	eb definitely depends on ea
 */

int el_depends(elem *ea,elem *eb)
{
 L1:
    elem_debug(ea);
    elem_debug(eb);
    switch (ea->Eoper)
    {
	case OPbit:
	    ea = ea->E1;
	    goto L1;
	case OPvar:
	case OPind:
	    break;
	default:
	    assert(0);
    }
    switch (eb->Eoper)
    {
	case OPconst:
	case OPrelconst:
	case OPstring:
#if SCPP
	case OPsizeof:
#endif
	    goto Lnodep;
	case OPvar:
	    if (ea->Eoper == OPvar && ea->EV.sp.Vsym != eb->EV.sp.Vsym)
		goto Lnodep;
	    break;
	default:
	    break;	// this could use improvement
    }
    return 1;

Lnodep:
    return 0;
}
#endif

/**************************
 * Make an elem out of a symbol, PIC style.
 */

#if TARGET_OSX

elem *el_picvar(symbol *s)
{   elem *e;
    int x;

    //printf("el_picvar(s = '%s')\n", s->Sident);
    //printf("  Sclass = "); WRclass((enum SC) s->Sclass); printf("\n");
    //symbol_print(s);
    symbol_debug(s);
    type_debug(s->Stype);
    e = el_calloc();
    e->Eoper = OPvar;
    e->EV.sp.Vsym = s;
    e->Ety = s->ty();

    switch (s->Sclass)
    {
	case SCstatic:
	case SClocstat:
	    x = 0;
	    goto case_got;

	case SCcomdat:
	case SCcomdef:
	case SCglobal:
	case SCextern:
	    if (s->Stype->Tty & mTYthread)
		x = 0;
	    else
		x = 1;
	case_got:
	{   if (!localgot)
	    {
		//localgot = symbol_generate(SCtmp,type_fake(TYnptr));
		char name[15];
		static int tmpnum;
		sprintf(name, "_LOCALGOT%d", tmpnum++);
		localgot = symbol_name(name, SCtmp, type_fake(TYnptr));
		symbol_add(localgot);
		localgot->Sfl = FLtmp;
		localgot->Sflags = SFLfree | SFLunambig | GTregcand;
	    }
	    int op = e->Eoper;
	    tym_t tym = e->Ety;
	    e->Eoper = OPrelconst;
	    e->Ety = TYnptr;
	    e = el_bin(OPadd, TYnptr, e, el_var(localgot));

	    if (s->Stype->Tty & mTYthread)
	    {
		if (!tls_get_addr_sym)
		{
		    /* void *___tls_get_addr(void *ptr);
		     * Parameter ptr is passed in EAX, matching TYjfunc calling convention.
		     */
		    tls_get_addr_sym = symbol_name("___tls_get_addr",SCglobal,type_fake(TYjfunc));
		    symbol_keep(tls_get_addr_sym);
		}
		e = el_bin(OPcall, TYnptr, el_var(tls_get_addr_sym), e);
	    }


	    switch (op * 2 + x)
	    {
		case OPvar * 2 + 1:
		    e = el_una(OPind, TYnptr, e);
		    e = el_una(OPind, TYnptr, e);
		    break;
		case OPvar * 2 + 0:
		case OPrelconst * 2 + 1:
		    e = el_una(OPind, TYnptr, e);
		    break;
		case OPrelconst * 2 + 0:
		    break;
		default:
		    assert(0);
		    break;
	    }
	    e->Ety = tym;
	    break;
	}
	default:
	    break;
    }
    return e;
}
#endif
#if TARGET_LINUX

elem *el_picvar(symbol *s)
{   elem *e;
    int x;

    //printf("el_picvar(s = '%s')\n", s->Sident);
    symbol_debug(s);
    type_debug(s->Stype);
    e = el_calloc();
    e->Eoper = OPvar;
    e->EV.sp.Vsym = s;
    e->Ety = s->ty();

    switch (s->Sclass)
    {
	/* local (and thread) symbols get only one level of indirection;
	 * all globally known symbols get two.
	 */
	case SCstatic:
	case SClocstat:
	    x = 0;
	    goto case_got;

	case SCcomdat:
	case SCcomdef:
	case SCglobal:
	case SCextern:
	    if (s->Stype->Tty & mTYthread)
		x = 0;
	    else
		x = 1;
	case_got:
	{   if (!localgot)
	    {
		//localgot = symbol_generate(SCtmp,type_fake(TYnptr));
		char name[15];
		static int tmpnum;
		sprintf(name, "_LOCALGOT%d", tmpnum++);
		localgot = symbol_name(name, SCtmp, type_fake(TYnptr));
		symbol_add(localgot);
		localgot->Sfl = FLtmp;
		localgot->Sflags = SFLfree | SFLunambig | GTregcand;
	    }
	    int op = e->Eoper;
	    tym_t tym = e->Ety;
	    e->Eoper = OPrelconst;
	    e->Ety = TYnptr;
	    e = el_bin(OPadd, TYnptr, e, el_var(localgot));

	    if (s->Stype->Tty & mTYthread)
	    {
		/* Add "volatile" to prevent e from being common subexpressioned.
		 * This is so we can preserve the magic sequence of instructions
		 * that the gnu linker patches:
		 *   lea EAX,x@tlsgd[EBX], call __tls_get_addr@plt
		 *      =>
		 *   mov EAX,gs[0], sub EAX,x@tpoff
		 * elf32-i386.c
		 */
		e->Ety |= mTYvolatile;
		if (!tls_get_addr_sym)
		{
		    /* void *___tls_get_addr(void *ptr);
		     * Parameter ptr is passed in EAX, matching TYjfunc calling convention.
		     */
		    tls_get_addr_sym = symbol_name("___tls_get_addr",SCglobal,type_fake(TYjfunc));
		    symbol_keep(tls_get_addr_sym);
		}
		e = el_bin(OPcall, TYnptr, el_var(tls_get_addr_sym), e);
	    }

	    switch (op * 2 + x)
	    {
		case OPvar * 2 + 1:
		    e = el_una(OPind, TYnptr, e);
		    e = el_una(OPind, TYnptr, e);
		    break;
		case OPvar * 2 + 0:
		case OPrelconst * 2 + 1:
		    e = el_una(OPind, TYnptr, e);
		    break;
		case OPrelconst * 2 + 0:
		    break;
		default:
		    assert(0);
		    break;
	    }
	    e->Ety = tym;
	    break;
	}
	default:
	    break;
    }
    return e;
}
#endif

/**************************
 * Make an elem out of a symbol.
 */

#if MARS
elem * el_var(symbol *s)
{   elem *e;

    //printf("el_var(s = '%s')\n", s->Sident);
    //printf("%x\n", s->Stype->Tty);
#if TARGET_LINUX || TARGET_OSX
    if (config.flags3 & CFG3pic &&
	!tyfunc(s->ty()))
	// Position Independent Code
	return el_picvar(s);
#endif
    symbol_debug(s);
    type_debug(s->Stype);
    e = el_calloc();
    e->Eoper = OPvar;
    e->EV.sp.Vsym = s;
    type_debug(s->Stype);
    e->Ety = s->ty();
    if (s->Stype->Tty & mTYthread)
    {
#if TARGET_LINUX || TARGET_OSX
	;		// add GS: override in back end
#else
	/*
		mov	EAX,FS:__tls_array
		mov	ECX,__tls_index
		mov	EAX,[ECX*4][EAX]
		inc	dword ptr _t[EAX]

		e => *(&s + *(FS:_tls_array + _tls_index * 4))

		If this is an executable app, not a dll, _tls_index
		can be assumed to be 0.
	 */
	elem *e1,*e2,*ea;

	e1 = el_calloc();
	e1->Eoper = OPrelconst;
	e1->EV.sp.Vsym = s;
	e1->Ety = TYnptr;

	if (config.wflags & WFexe)
	{
	    // e => *(&s + *(FS:_tls_array))
	    e2 = el_var(rtlsym[RTLSYM_TLS_ARRAY]);
	}
	else
	{
	    e2 = el_bin(OPmul,TYint,el_var(rtlsym[RTLSYM_TLS_INDEX]),el_long(TYint,4));
	    ea = el_var(rtlsym[RTLSYM_TLS_ARRAY]);
	    e2 = el_bin(OPadd,ea->Ety,ea,e2);
	}
	e2 = el_una(OPind,TYint,e2);
	
	e->Eoper = OPind;
	e->E1 = el_bin(OPadd,e1->Ety,e1,e2);
	e->E2 = NULL;
#endif
    }
    return e;
}
#elif SCPP
elem * el_var(symbol *s)
{   elem *e;

    //printf("el_var(s = '%s')\n", s->Sident);
#if TARGET_LINUX || TARGET_OSX
    if (config.flags3 & CFG3pic && !tyfunc(s->ty()))
	return el_picvar(s);
#endif
    symbol_debug(s);
    type_debug(s->Stype);
    e = el_calloc();
    e->Eoper = OPvar;
    e->EV.sp.Vsym = s;
    if (SCPP && PARSER)
#if TX86 && TARGET_WINDOS
    {	type *t = s->Stype;

	type_debug(t);
	e->ET = t;
	t->Tcount++;
	switch (t->Tty & (mTYimport | mTYthread))
	{   case mTYimport:
		obj_import(e);
		break;
	    case mTYthread:
	/*
		mov	EAX,FS:__tls_array
		mov	ECX,__tls_index
		mov	EAX,[ECX*4][EAX]
		inc	dword ptr _t[EAX]

		e => *(&s + *(FS:_tls_array + _tls_index * 4))
	 */
#if MARS
		assert(0);
#else
	    {	elem *e1,*e2,*ea;

		e1 = el_calloc();
		e1->Eoper = OPrelconst;
		e1->EV.sp.Vsym = s;
		e1->ET = newpointer(s->Stype);
		e1->ET->Tcount++;

		e2 = el_bint(OPmul,tsint,el_var(rtlsym[RTLSYM_TLS_INDEX]),el_longt(tsint,4));
		ea = el_var(rtlsym[RTLSYM_TLS_ARRAY]);
		e2 = el_bint(OPadd,ea->ET,ea,e2);
		e2 = el_unat(OPind,tsint,e2);
		
		e->Eoper = OPind;
		e->E1 = el_bint(OPadd,e1->ET,e1,e2);
		e->E2 = NULL;
	    }
#endif
		break;
	    case mTYthread | mTYimport:
		assert(SCPP);
#if SCPP
		tx86err(EM_thread_and_dllimport,s->Sident);	// can't be both thread and import
#endif
		break;
	}
    }
#else
    {	type_debug(s->Stype);
	e->ET = s->Stype;
	e->ET->Tcount++;
    }
#endif
    else
	e->Ety = s->ty();
    return e;
}
#endif

/**************************
 * Make a pointer to an elem out of a symbol.
 */

elem * el_ptr(symbol *s)
{
    elem *e;

    //printf("el_ptr(s = '%s')\n", s->Sident);
    //printf("el_ptr\n");
    symbol_debug(s);
    type_debug(s->Stype);
#if TARGET_OSX
    if (config.flags3 & CFG3pic && tyfunc(s->ty()))
    {
	/* Cannot access address of code from code.
	 * Instead, create a data variable, put the address of the
	 * code in that data variable, and return the elem for
	 * that data variable.
	 */
	symbol *sd = symboldata(Doffset, TYnptr);
	Doffset += reftoident(DATA, Doffset, s, 0, CFoff);
	e = el_picvar(sd);
	return e;
    }
#endif
#if TARGET_LINUX || TARGET_OSX
    if (config.flags3 & CFG3pic && tyfunc(s->ty()))
	e = el_picvar(s);
    else
#endif
	e = el_var(s);
#if SCPP
    if (PARSER)
    {	type_debug(e->ET);
	e = el_unat(OPaddr,type_ptr(e,e->ET),e);
    }
    else
#endif
    if (e->Eoper == OPvar)
    {
	e->Ety = TYnptr;
	e->Eoper = OPrelconst;
    }
    else
    {	e = el_una(OPaddr, TYnptr, e);
	e = doptelem(e, GOALvalue | GOALflags);
    }
    return e;
}

/**************************
 * Make a pointer to an elem out of a symbol at offset.
 */

#if SCPP

elem * el_ptr_offset(symbol *s,targ_size_t offset)
{   elem *e;
    elem *e1;

    e = el_ptr(s);	/* e is an elem which is a pointer to s	*/
    e1 = e->E1;
    if (e1->Eoper == OPvar)
	;
    // The following case happens if symbol s is in thread local storage
    else if (e1->Eoper == OPind &&
	     e1->E1->Eoper == OPadd &&
	     e1->E1->E1->Eoper == OPrelconst)
	e1 = e1->E1->E1;
    else
	assert(0);
    assert(e1->EV.sp.Vsym == s);
    e1->EV.sp.Voffset = offset;
    return e;
}

#endif

/*************************
 * Returns:
 *	!=0	elem evaluates right-to-left
 *	0	elem evaluates left-to-right
 */

HINT ERTOL(elem *e)
{
    elem_debug(e);
    assert(!PARSER);
#if TX86
    return OTrtol(e->Eoper) &&
	(!OTopeq(e->Eoper) || config.inline8087 || !tyfloating(e->Ety));
#else
    return OTrtol(e->Eoper);
#endif
}

/********************************
 * Return !=0 if expression never returns.
 * Does not detect all cases, errs on the side of saying it returns.
 */

int el_noreturn(elem *e)
{   int result = 0;

    while (1)
    {	elem_debug(e);
	switch (e->Eoper)
	{   case OPcomma:
		if (result |= el_noreturn(e->E1))
		    break;
		e = e->E2;
		continue;

	    case OPcall:
	    case OPucall:
		e = e->E1;
		if (e->Eoper == OPvar && e->EV.sp.Vsym->Sflags & SFLexit)
		    result = 1;
		break;

	    case OPhalt:
		result = 1;
		break;

	    default:
		break;
	}
	break;
    }
    return result;
}

/********************************
 * Scan down commas and return the controlling elem.
 */

elem *el_scancommas(elem *e)
{
    while (e->Eoper == OPcomma)
	e = e->E2;
    return e;
}

#if (TARGET_POWERPC)
void el_convconst(elem *e)
{

    int i;
    symbol *s;
    long    *	p;
    targ_size_t len;
    struct CONST_VALUE {
#if !DDRT
    	long	val[2];			// Largest floating constant is 8 bytes
#else
	fix!!
#endif
    	symbol 	*s;			// Symbol for that floating constant
    } *pcv;
    
    static list_t value_list;
    list_t pcl;
    
    tym_t	tym;
    type * T;
//    float cnv_float;	// the compiler stores all constants in double accuracy
			// hence when the elem is of type TYfloat we have to
			// implicitly convert it from double to float
    assert(!PARSER);
    elem_debug(e);

    assert(e->Eoper == OPconst);
    

    tym = tybasic(typemask(e));
    
    assert(tyfloating(tym));	// it shouldn't get here otherwise....

#if !DDRT
	// all float constants are stored as doubles
	// NOTE at this point double and long double are the same (11/18/93 -udi-)
	if (tym == TYdouble || tym == TYldouble) {
//		tym = TYdouble;
		p = (long *) &e->EV.Vdouble;
	} else {
		p = (long *) &e->EV.Vfloat;

//		cnv_float = e->EV.Vdouble;
//		p = (long *) & cnv_float;
 	}

#else
	fix!!
#endif
	
	
	
	
//
// Look for another floating constant with the identical value
// linear list should be fast enough, How many floating constants are there
// that appear in trees.  Any that appear in data declarations, etc. are already
// taken care of elsewhere
//
	for (pcl = value_list;pcl; pcl = list_next(pcl)) {
	    pcv = (CONST_VALUE *) list_ptr( pcl );
	    if (tysize[tym] == type_size(pcv->s->Stype) &&
		!memcmp( pcv->val, p, tysize[tym])) {
		s = pcv->s;
		goto returnelem;
	    }   
	}

    // Replace float with a symbol that refers to a float constant stored
    // in the DATA segment
    
	tym |= mTYconst; 
 	T = type_alloc( tym );
	s = symbol_generate( SCstatic, T);
	s->Sfl = FLdatseg;

	pcv = (CONST_VALUE *) MEM_PARC_CALLOC(sizeof(CONST_VALUE));
	memcpy( pcv->val, p, type_size(T));
	pcv->s = s;
	list_append( &value_list, pcv );
	
	obj_module( s, STYP_DATA, 0 );
	obj_bytes( STYP_DATA, type_size(T), p);

	
	// NOTE: unlike el_convstring() i'm not implementing any machinery for
	// remembering already defined constant floats. on a rare occasion that
	// may create duplications, however i don't think it warrants the extra
	// effort. should it become necessary, i'll do it. (-udi-  11/7/93)

returnelem:
    // Refer e to the symbol generated
    e->Ety = tym;
    e->Eoper = OPvar;
    e->EV.sp.Vsym = s;
    e->EV.sp.Voffset = 0;	// making sure no remnants of the float constat
    				// appear as some kind of offset into the var
}	// el_convconst
#endif

/************************************
 * Convert floating point constant to a read-only symbol.
 * Needed iff floating point code can't load immediate constants.
 */

elem *el_convfloat(elem *e)
{
#if TX86
    assert(config.inline8087);
    if (tycomplex(e->Ety))
    {
	if (loadconst(e, 0) && loadconst(e, 1))
	    return e;
    }
    else if (loadconst(e, 0))
	return e;
    changes++;
    int sz = tysize(e->Ety);
#if LNGDBLSIZE == 12
    if (sz == 12 || sz == 24)
    {
	unsigned short *p = (unsigned short *)&e->EV.Vfloat;
	p[5] = 0;		// fill in 2 byte hole
	if (sz == 24)
	    p[11] = 0;		// other 2 byte hole
    }
#endif
#if LNGDBLSIZE == 16
    if ((sz == 16 && !tycomplex(e->Ety)) || sz == 32)
    {
	unsigned short *p = (unsigned short *)&e->EV.Vfloat;
	p[5] = 0;		// fill in 6 byte hole
	p[6] = 0;
	p[7] = 0;
	if (sz == 32)
	{   p[13] = 0;		// other 6 byte hole
	    p[14] = 0;
	    p[15] = 0;
	}
    }
#endif
#if 0
    printf("el_convfloat() %g %g sz=%d\n", e->EV.Vcdouble.re, e->EV.Vcdouble.im, sz);
printf("el_convfloat(): sz = %d\n", sz);
unsigned short *p = (unsigned short *)&e->EV.Vcldouble;
for (int i = 0; i < sz/2; i++) printf("%04x ", p[i]);
printf("\n");
#endif
    symbol *s  = out_readonly_sym(e->Ety, &e->EV.Vfloat, sz);
    tym_t ty = e->Ety;
    el_free(e);
    e = el_var(s);
    e->Ety = ty;
    if (e->Eoper == OPvar)
	e->Ety |= mTYconst;
    //printf("s: %s %d:x%x\n", s->Sident, s->Sseg, s->Soffset);
#endif
    return e;
}

/********************************
 * Convert reference to a string to reference to a symbol
 * stored in the static data segment.
 */

elem *el_convstring(elem *e)
{
    //printf("el_convstring()\n");
    int i;
    symbol *s;
    char *p;
    targ_size_t len;

    assert(!PARSER);
    elem_debug(e);
    assert(e->Eoper == OPstring);
    p = e->EV.ss.Vstring;
    e->EV.ss.Vstring = NULL;
    len = e->EV.ss.Vstrlen;

#if TX86
    // Handle strings that go into the code segment
    if (tybasic(e->Ety) == TYcptr ||
	(tyfv(e->Ety) && config.flags3 & CFG3strcod))
    {
	assert(OMFOBJ); 	// option not done yet for others
	s = symbol_generate(SCstatic, type_fake(mTYcs | e->Ety));
	s->Sfl = FLcsdata;
	s->Soffset = Coffset;
	s->Sseg = cseg;
	symbol_keep(s);
	if (!eecontext.EEcompile || eecontext.EEin)
	{   obj_bytes(cseg,Coffset,len,p);
	    Coffset += len;
	}
	mem_free(p);
	goto L1;
    }
#endif

#if TARGET_68K
    /*
     * When using PC relative strings, strings cannot be saved because this
     * would lead to problems.  We do not know how to emit PC-relative
     * relocations for stuff in other functions.
     */
    if (!(PCrel_option & PC_STRINGS))
#endif

    if (eecontext.EEin)			// if compiling debugger expression
    {
	s = out_readonly_sym(e->Ety, p, len);
	mem_free(p);
	goto L1;
    }

    // See if e is already in the string table
    for (i = 0; i < arraysize(stable); i++)
    {	if (stable[i].len == len &&
	    memcmp(stable[i].p,p,len) == 0)
	{
	    // Replace e with that symbol
	    MEM_PH_FREE(p);
	    s = stable[i].sym;
	    goto L1;
	}
    }

    // Replace string with a symbol that refers to that string
    // in the DATA segment

#if TX86
    if (eecontext.EEcompile)
	s = symboldata(Doffset,e->Ety);
    else
	s = out_readonly_sym(e->Ety,p,len);

    // Remember the string for possible reuse later
    //dbg_printf("Adding %d, '%s'\n",stable_si,p);
    mem_free(stable[stable_si].p);
    stable[stable_si].p   = p;
    stable[stable_si].len = len;
    stable[stable_si].sym = s;
    stable_si = (stable_si + 1) & (arraysize(stable) - 1);

#else
#if TARGET_POWERPC
    s = symbol_generate( SCstatic, obj_charstr_type(len));
    s->Sfl = FLdatseg;
    obj_module( s, STYP_DATA, 0 );
    obj_bytes( STYP_DATA, len, p );
#else
    s = symboldata(Doffset,e->Ety);
#if TARGET_68K
    if (PCrel_option & PC_STRINGS)
    {	s = symbol_generate(SCstatic,type_fake(e->Ety));
	s->Sfl = FLoffset;		// relative offset from code
	symbol_keep(s);
	s->Sidnum = obj_PCrel_start();
	for (i=0; i<len; ++i)
	    obj_PCrel_byte(p[i]);
    }
    else
#endif
    {   s->Sfl = FLdatseg;		// string in data segment
        s->Sidnum = obj_module(DATA,SClocstat,0);
        obj_bytes(DATA,0,len,p);
    }
#endif

#if TARGET_68K
    /*
     * When using PC relative strings, strings cannot be saved because this
     * would lead to problems.  We do not know how to emit PC-relative
     * relocations for stuff in other functions.
     */
    if (!(PCrel_option & PC_STRINGS)) 
#endif
    {
	// Remember the string for possible reuse later
	//dbg_printf("Adding %d, '%s'\n",stable_si,p);
	MEM_PH_FREE(stable[stable_si].p);
	stable[stable_si].p   = p;
	stable[stable_si].len = len;
	stable[stable_si].sym = s;
	stable_si = (stable_si + 1) & (arraysize(stable) - 1);
    }
#endif

L1:
    // Refer e to the symbol generated
    elem *ex = el_ptr(s);
    ex->Ety = e->Ety;
    if (e->EV.ss.Voffset)
    {
	if (ex->Eoper == OPrelconst)
	     ex->EV.sp.Voffset += e->EV.ss.Voffset;
	else
	     ex = el_bin(OPadd, ex->Ety, ex, el_long(TYint, e->EV.ss.Voffset));
    }
    el_free(e);
    return ex;
}

/*************************
 * Run through a tree converting it to CODGEN.
 */

elem *el_convert(elem *e)
{   int op;

    //printf("el_convert(%p)\n", e);
    elem_debug(e);
    op = e->Eoper;
    switch (op)
    {
	case OPvar:
	    break;

	case OPconst:
#if TX86
	    if (tyfloating(e->Ety) && config.inline8087)
		e = el_convfloat(e);
#endif
	    break;

	case OPstring:
	    changes++;
	    e = el_convstring(e);
	    break;

	default:
	    if (OTbinary(op))
	    {
		e->E1 = el_convert(e->E1);
		e->E2 = el_convert(e->E2);
	    }
	    else if (OTunary(op))
	    {
		e->E1 = el_convert(e->E1);
	    }
	    break;
    }
    return e;
}


/************************
 * Make a constant elem.
 *	ty	= type of elem
 *	*pconst	= union of constant data
 */

elem * el_const(tym_t ty,union eve *pconst)
{   elem *e;

    assert(MARS || !PARSER);
    e = el_calloc();
    e->Eoper = OPconst;
    e->Ety = ty;
    memcpy(&e->EV,pconst,sizeof(e->EV));
    return e;
}

#if SCPP

/**************************
 * Insert constructor information into tree.
 */

elem *el_ctor(elem *ector,elem *e,symbol *sdtor)
{
    //printf("el_ctor(ector = %p, e = %p, sdtor = %p)\n", ector, e, sdtor);
    //printf("stdor = '%s'\n", cpp_prettyident(sdtor));
    //printf("e:\n"); elem_print(e);
    if (ector)
    {
	if (sdtor)
	{
	    if (sdtor->Sfunc->Fbody)
	    {
		n2_instantiate_memfunc(sdtor);
	    }
	    // Causes symbols to be written out prematurely when
	    // writing precompiled headers.
	    // Moved to outelem().
	    //nwc_mustwrite(sdtor);
	}
	if (!sdtor || ector->Eoper == OPcall ||
	    (ector->Eoper == OPrelconst && !(sytab[ector->EV.sp.Vsym->Sclass] & SCSS))
#if TX86
	    // Not ambient memory model
	    || (tyfarfunc(sdtor->ty()) ? !LARGECODE : LARGECODE)
#endif
	   )
	{
	    el_free(ector);
	}
	else
	{
	    ector = el_unat(OPctor,ector->ET,ector);
	    symbol_debug(sdtor);
	    ector->EV.eop.Edtor = sdtor;
	    symbol_debug(sdtor);
	    if (e)
		e = el_bint(OPinfo,e->ET,ector,e);
	    else
		e = ector;
	}
    }
    return e;
}

/**************************
 * Insert destructor information into tree.
 */

elem *el_dtor(elem *edtor,elem *e)
{
    if (edtor)
    {
	edtor = el_unat(OPdtor,edtor->ET,edtor);
	if (e)
	    e = el_bint(OPcomma,e->ET,edtor,e);
	else
	    e = edtor;
    }
    return e;
}

#endif

/**********************************
 * Create an elem of the constant 0, of the type t.
 */

elem *el_zero(type *t)
{
	elem *e;
	
	assert(PARSER);
	
	e = el_calloc();
    	e->Eoper = OPconst;
    	e->ET = t;
	if (t)
	{	
	    type_debug(t);
	    e->ET->Tcount++;
	}
	return(e);
}

/*******************
 * Find and return pointer to parent of e starting at *pe.
 * Return NULL if can't find it.
 */

elem ** el_parent(elem *e,elem **pe)
{
  assert(e && pe && *pe);
  elem_debug(e);
  elem_debug(*pe);
  if (e == *pe)
	return pe;
  else if (OTunary((*pe)->Eoper))
	return el_parent(e,&((*pe)->E1));
  else if (OTbinary((*pe)->Eoper))
  {	elem **pe2;

	return ((pe2 = el_parent(e,&((*pe)->E1))) != 0) ? pe2
						 : el_parent(e,&((*pe)->E2));
  }
  else
	return NULL;
}

/*******************************
 * Return !=0 if trees match.
 */

static int gmatch2;			// kludge for el_match2()

int el_match(elem *n1,elem *n2)
{   unsigned op;
    tym_t tym,tym2;

L1:
    if (n1 == n2)
	return TRUE;
    if (!n1 || !n2)
	goto nomatch;
    elem_debug(n1);
    elem_debug(n2);

    if ((op = n1->Eoper) != n2->Eoper)
	goto nomatch;

    if ((tym = typemask(n1)) != (tym2 = typemask(n2)))
    {
#if TX86
	if ((tym & ~mTYbasic) != (tym2 & ~mTYbasic))
#else
	if ((tym & ~mTYbasic & ~mTYMAN) != (tym2 & ~mTYbasic & ~mTYMAN))
#endif
	{
	    if (!(gmatch2 & 2))
		goto nomatch;
	}
	tym = tybasic(tym);
	tym2 = tybasic(tym2);
	if (tyequiv[tym] != tyequiv[tym2])
	    goto nomatch;
    }

  if (OTunary(op))
  {
    L2:
	if (PARSER)
	{
	    n1 = n1->E1;
	    n2 = n2->E1;
	    assert(n1 && n2);
	    goto L1;
	}
	else if (OPTIMIZER)
	{
	    if (op == OPstrpar || op == OPstrctor)
	    {	if (n1->Enumbytes != n2->Enumbytes)
		    goto nomatch;
	    }
	    n1 = n1->E1;
	    n2 = n2->E1;
	    assert(n1 && n2);
	    goto L1;
	}
	else
	{
	    if (n1->E1 == n2->E1)
		goto ismatch;
	    n1 = n1->E1;
	    n2 = n2->E1;
	    assert(n1 && n2);
	    goto L1;
	}
  }
  else if (OTbinary(op))
  {
	if (!PARSER)
	{
	    if (op == OPstreq)
	    {	if (n1->Enumbytes != n2->Enumbytes)
		    goto nomatch;
	    }
	}
	if (el_match(n1->E2,n2->E2))
	{
	    goto L2;	// check left tree
	}
	goto nomatch;
  }
  else /* leaf elem */
  {	unsigned n;

	switch (op)
	{
	    case OPconst:
		if (gmatch2 & 1)
		    break;
	    Lagain:
		switch (tybasic(tym))
		{
		    case TYshort:
		    case TYwchar_t:
		    case TYushort:
		    case_short:
			if (n1->EV.Vshort != n2->EV.Vshort)
				goto nomatch;
			break;
		    case TYlong:
		    case TYulong:
		    case TYdchar:
#if TARGET_MAC
		    case TYfptr:
		    case TYvptr:
#endif
		    case_long:
			if (n1->EV.Vlong != n2->EV.Vlong)
				goto nomatch;
			break;
		    case TYllong:
		    case TYullong:
		    case_llong:
			if (n1->EV.Vllong != n2->EV.Vllong)
				goto nomatch;
			break;
		    case TYenum:
			if (PARSER)
			{   tym = n1->ET->Tnext->Tty;
			    goto Lagain;
			}
		    case TYint:
		    case TYuint:
			if (intsize == SHORTSIZE)
			    goto case_short;
			else
			    goto case_long;

#if TX86
#if JHANDLE
                    case TYjhandle:
#endif
		    case TYnptr:
		    case TYsptr:
		    case TYcptr:
			if (NPTRSIZE == SHORTSIZE)
			    goto case_short;
			else if (NPTRSIZE == LONGSIZE)
			    goto case_long;
			else
			{   assert(NPTRSIZE == LLONGSIZE);
			    goto case_llong;
			}
#endif

		    case TYbool:
		    case TYchar:
		    case TYuchar:
		    case TYschar:
			if (n1->EV.Vschar != n2->EV.Vschar)
				goto nomatch;
			break;
#if TX86
		    case TYfptr:
		    case TYhptr:
		    case TYvptr:

			/* Far pointers on the 386 are longer than
			   any integral type...
			 */
			if (memcmp(&n1->EV,&n2->EV,tysize[tybasic(tym)]))
			    goto nomatch;
			break;
#endif
#if !DDRT
			/* Compare bit patterns w/o worrying about
			   exceptions, unordered comparisons, etc.
			 */
		    case TYfloat:
		    case TYifloat:
			if (memcmp(&n1->EV,&n2->EV,sizeof(n1->EV.Vfloat)))
			    goto nomatch;
			break;

		    case TYdouble:
		    case TYdouble_alias:
		    case TYidouble:
			if (memcmp(&n1->EV,&n2->EV,sizeof(n1->EV.Vdouble)))
			    goto nomatch;
			break;

		    case TYldouble:
		    case TYildouble:
#if LNGDBLSIZE > 10
			/* sizeof is 12, but actual size is 10 */
			if (memcmp(&n1->EV,&n2->EV,10))
#else
			if (memcmp(&n1->EV,&n2->EV,sizeof(n1->EV.Vldouble)))
#endif
			    goto nomatch;
			break;

		    case TYcfloat:
			if (memcmp(&n1->EV,&n2->EV,sizeof(n1->EV.Vcfloat)))
			    goto nomatch;
			break;

		    case TYcdouble:
			if (memcmp(&n1->EV,&n2->EV,sizeof(n1->EV.Vcdouble)))
			    goto nomatch;
			break;

		    case TYcldouble:
#if LNGDBLSIZE > 10
			/* sizeof is 12, but actual size of each part is 10 */
			if (memcmp(&n1->EV,&n2->EV,10) ||
			    memcmp(&n1->EV.Vldouble + 1, &n2->EV.Vldouble + 1, 10))
#else
			if (memcmp(&n1->EV,&n2->EV,sizeof(n1->EV.Vcldouble)))
#endif
			    goto nomatch;
			break;
#else /* DDRT */
		    case TYfloat:
		    	if (memcmp(&n1->EV.Vfloat,&n2->EV.Vfloat,FLOATSIZE))
			    goto nomatch;
			break;
		    case TYdouble:
		    	if (memcmp(&n1->EV.Vdouble,&n2->EV.Vdouble,DOUBLESIZE))
			    goto nomatch;
		    case TYldouble:
#if TARGET_POWERPC
		    	if (config.flags & CFGldblisdbl)
			{
		    	    if (memcmp(&n1->EV.Vdouble,&n2->EV.Vdouble,DOUBLESIZE))
			    	goto nomatch;
			}
			else 
#endif
			if (memcmp(&n1->EV.Vldouble,&n2->EV.Vldouble,LNGDBLSIZE))
			    	goto nomatch;
			break;
#endif /* DDRT */
		    case TYvoid:
			break;			// voids always match
#if SCPP
		    case TYident:
			assert(errcnt);
			goto nomatch;
#endif
		    default:
#ifdef DEBUG
			elem_print(n1);
#endif
			assert(0);
		}
		break;
	    case OPrelconst:
	    case OPvar:
#if SCPP
	    case OPsizeof:
#endif
		symbol_debug(n1->EV.sp.Vsym);
		symbol_debug(n2->EV.sp.Vsym);
		if (n1->EV.sp.Voffset != n2->EV.sp.Voffset)
		    goto nomatch;
#if SCPP
		if (gmatch2 & 4)
		{
#if 0
		    printf("------- symbols ---------\n");
		    symbol_print(n1->EV.sp.Vsym);
		    symbol_print(n2->EV.sp.Vsym);
		    printf("\n");
#endif
		    if (/*strcmp(n1->EV.sp.Vsym->Sident, n2->EV.sp.Vsym->Sident) &&*/
			n1->EV.sp.Vsym != n2->EV.sp.Vsym &&
			(!n1->EV.sp.Vsym->Ssequence || n1->EV.sp.Vsym->Ssequence != n2->EV.sp.Vsym->Ssequence))
			goto nomatch;
		}
		else
#endif
		{
		    if (n1->EV.sp.Vsym != n2->EV.sp.Vsym)
			goto nomatch;
		}
		break;
	    case OPasm:
#if TARGET_MAC
		if ((n1->Eflags&EFsmasm && !(n2->Eflags&EFsmasm)) ||
		    (n2->Eflags&EFsmasm && !(n1->Eflags&EFsmasm)) ||
		    (n1->EV.mac.Vasmdat[0] != n2->EV.mac.Vasmdat[0]) ||
		   (n1->EV.mac.Vasmdat[1] != n2->EV.mac.Vasmdat[1]) )
		   	goto nomatch;
		if (n1->Eflags&EFsmasm)
			break;		/* flags & data match,otherwise check strings */
#endif
	    case OPstring:
	    case OPhstring:
		if (n1->EV.ss.Vstrlen != (n = n2->EV.ss.Vstrlen) ||
		    n1->EV.ss.Voffset != n2->EV.ss.Voffset ||
		    memcmp(n1->EV.ss.Vstring,n2->EV.ss.Vstring,n))
			goto nomatch;	/* check bytes in the string	*/
		break;
	    case OPstrthis:
	    case OPframeptr:
	    case OPhalt:
	    case OPgot:
		break;
#if SCPP
	    case OPmark:
		break;
#endif
	    default:
#ifdef DEBUG
		WROP(op);
#endif
		assert(0);
	}
ismatch:
	return TRUE;
  }
  assert(0);
  /* NOTREACHED */

nomatch:
  return FALSE;
}

/*********************************
 * Kludge on el_match(). Same, but ignore differences in OPconst.
 */

int el_match2(elem *n1,elem *n2)
{   int result;

    gmatch2 = 1;
    result = el_match(n1,n2);
    gmatch2 = 0;
    return result;
}

/*********************************
 * Kludge on el_match(). Same, but ignore differences in type modifiers.
 */

int el_match3(elem *n1,elem *n2)
{   int result;

    gmatch2 = 2;
    result = el_match(n1,n2);
    gmatch2 = 0;
    return result;
}

/*********************************
 * Kludge on el_match(). Same, but ignore differences in spelling of var's.
 */

int el_match4(elem *n1,elem *n2)
{   int result;

    gmatch2 = 2|4;
    result = el_match(n1,n2);
    gmatch2 = 0;
    return result;
}

/******************************
 * Extract long value from constant parser elem.
 */

targ_llong el_tolongt(elem *e)
{   targ_llong result;
    char parsersave = PARSER;

    PARSER = 1;
    result = el_tolong(e);
    PARSER = parsersave;
    return result;
}

/******************************
 * Extract long value from constant elem.
 */

targ_llong el_tolong(elem *e)
{   targ_llong result;
    tym_t ty;

    elem_debug(e);
#if SCPP
    if (e->Eoper == OPsizeof)
    {
	e->Eoper = OPconst;
	e->EV.Vllong = type_size(e->EV.sp.Vsym->Stype);
    }
#endif
#ifdef DEBUG
    if (e->Eoper != OPconst)
	elem_print(e);
#endif
    assert(e->Eoper == OPconst);
    ty = tybasic(typemask(e));
L1:
    switch (ty)
    {   
	case TYchar:
	    if (config.flags & CFGuchar)
		goto Uchar;
	    /* FALL-THROUGH */
	case TYschar:
	    result = e->EV.Vschar;
	    break;
	case TYuchar:
	case TYbool:
	Uchar:
	    result = e->EV.Vuchar;
	    break;
	case TYshort:
	Ishort:
	    result = e->EV.Vshort;
	    break;
	case TYushort:
	case TYwchar_t:
	Ushort:
	    result = e->EV.Vushort;
	    break;
#if SCPP && TX86
	case TYenum:
	    assert(PARSER);
	    ty = e->ET->Tnext->Tty;
	    goto L1;
#endif

#if TX86
#if JHANDLE
	case TYjhandle:
#endif
	case TYnptr:
	case TYsptr:
	case TYcptr:
	    if (NPTRSIZE == SHORTSIZE)
		goto Ushort;
	    if (NPTRSIZE == LONGSIZE)
		goto Ulong;
	    if (NPTRSIZE == LLONGSIZE)
		goto Ullong;
	    assert(0);
#endif

#if TARGET_MAC // DJB
	case TYint:
	    if (intsize == SHORTSIZE)
		goto Ishort;
	    goto Ulong;
#if SCPP
	case TYenum:
#endif
#endif
	case TYuint:
	    if (intsize == SHORTSIZE)
		goto Ushort;
	    goto Ulong;

	case TYulong:
	case TYdchar:
	case TYfptr:
#if TX86
	case TYhptr:
#endif
	case TYvptr:
	case TYvoid:			/* some odd cases		*/
	Ulong:
	    result = e->EV.Vulong;
	    break;

#if TX86
	case TYint:
	    if (intsize == SHORTSIZE)
		goto Ishort;
	    goto Ilong;

	case TYlong:
	Ilong:
	    result = e->EV.Vlong;
	    break;
#endif
	case TYllong:
	case TYullong:
	Ullong:
	    result = e->EV.Vullong;
	    break;
	case TYdouble_alias:
	case TYldouble:
	case TYdouble:
	case TYfloat:
	case TYildouble:
	case TYidouble:
	case TYifloat:
	case TYcldouble:
	case TYcdouble:
	case TYcfloat:
#if !DDRT
	    result = (targ_llong)el_toldouble(e);
#else
	    result = Xxtoi(el_toldouble(e));
#endif
	    break;

#if SCPP
	case TYmemptr:
	    ty = tybasic(tym_conv(e->ET));
	    goto L1;
#endif
	default:
#if SCPP
	    // Can happen as result of syntax errors
	    assert(errcnt);
#else
	    assert(0);
#endif
    }
    return result;
}

/***********************************
 * Determine if constant e is all ones or all zeros.
 * Input:
 *	bit 0:	all zeros
 *	    1:	1
 *	   -1:	all ones
 */

int el_allbits(elem *e,int bit)
{   targ_llong value;

    elem_debug(e);
    assert(e->Eoper == OPconst);
    value = e->EV.Vullong;
    switch (tysize(e->Ety))
    {
	case 1:	value = (signed char) value;
		break;
	case 2:	value = (short) value;
		break;
	case 4: value = (long) value;
		break;
	case 8: break;
	default:
		assert(0);
    }
    if (bit == -1)
	value++;
    else if (bit == 1)
	value--;
    return value == 0;
}

/******************************
 * Extract long double value from constant elem.
 * Silently ignore types which are not floating point values.
 */

targ_ldouble el_toldouble(elem *e)
{   targ_ldouble result;

    elem_debug(e);
    assert(cnst(e));
#if TX86
    switch (tysize(typemask(e)))
    {
	case FLOATSIZE:		// TYfloat
	    result = e->EV.Vfloat;
	    break;
	case DOUBLESIZE:	// TYdouble
	    result = e->EV.Vdouble;
	    break;
	case LNGDBLSIZE:	// TYldouble
	    result = e->EV.Vldouble;
	    break;
    }
#else
#if !DDRT
    switch (tysize[tybasic(typemask(e))])
    {
    case FLOATSIZE:		// TYfloat
	result = e->EV.Vfloat;
	break;
    case DOUBLESIZE:	// TYdouble
	result = e->EV.Vdouble;
	break;
#if DOUBLESIZE != LNGDBLSIZE
    case LNGDBLSIZE:	// TYldouble
#ifdef LNGHDBLSIZE
    case LNGHDBLSIZE:
#endif
#if (TARGET_POWERPC)
	if (config.flags & CFGldblisdbl)
	    result = e->EV.Vdouble;
	else
#endif
	    result = e->EV.Vldouble;
	break;
#endif
    }
#else /* DDRT */
    switch (tysize[tybasic(typemask(e))])
    {
	case FLOATSIZE:		// TYfloat
	    result = Xftox(e->EV.Vfloat);
	    break;
	case DOUBLESIZE:	// TYdouble
	    result = Xdtox(e->EV.Vdouble);
	    break;
	case LNGDBLSIZE:	// TYldouble
#ifdef LNGHDBLSIZE
	case LNGHDBLSIZE:
#endif
#if TARGET_POWERPC
	    if (config.flags & CFGldblisdbl)
	    	result = Xdtox(e->EV.Vdouble);
	    else
#endif
	    	result = e->EV.Vldouble;
	    break;
    }
#endif /* DDRT */
#endif
    return result;
}

/********************************
 * Is elem type-dependent or value-dependent?
 * Return !=0 if so.
 */

int el_isdependent(elem *e)
{
    if (type_isdependent(e->ET))
	return 1;
    while (1)
    {
	if (e->PEFflags & PEFdependent)
	    return 1;
	if (OTunary(e->Eoper))
	    e = e->E1;
	else if (OTbinary(e->Eoper))
	{   if (el_isdependent(e->E2))
		return 1;
	    e = e->E1;
	}
	else
	    break;
    }
    return 0;
}

/*******************************
 * Check for errors in a tree.
 */

#ifdef DEBUG

void el_check(elem *e)
{
    elem_debug(e);
    while (1)
    {
	if (OTunary(e->Eoper))
	    e = e->E1;
	else if (OTbinary(e->Eoper))
	{   el_check(e->E2);
	    e = e->E1;
	}
	else
	    break;
    }
}

#endif

/*******************************
 * Write out expression elem.
 */

#ifdef DEBUG

void elem_print(elem *e)
{ static int nestlevel = 0;
  int i;
  tym_t tym;

  nestlevel++;
  for (i = nestlevel; --i;) dbg_printf(" ");
  dbg_printf("el:%p ",e);
  if (!e)
  {	dbg_printf("\n");
	goto ret;
  }
  elem_debug(e);
  if (configv.addlinenumbers)
  {
#if TX86
#if MARS
	dbg_printf("fil=%p lin=%u ",e->Esrcpos.Sfilename,e->Esrcpos.Slinnum);
#elif SCPP
	dbg_printf("fil=%p lin=%u ",e->Esrcpos.Sfilptr,e->Esrcpos.Slinnum);
#endif
#else
	dbg_printf("fil=%d lin=%u ",((struct ELEMsrcpos *)e)->Esrcpos.Sfilnum,
	((struct ELEMsrcpos *)e)->Esrcpos.Slinnum);
#endif
#if TARGET_MAC && SOURCE_OFFSETS
	dbg_printf("off %d) ",((struct ELEMsrcpos *)e)->Esrcpos.Sfiloff);
#endif
  }
  if (!PARSER)
  {	dbg_printf("cnt=%d ",e->Ecount);
	if (!OPTIMIZER)
	    dbg_printf("cs=%d ",e->Ecomsub);
  }
  WROP(e->Eoper);
  dbg_printf(" ");
  if (SCPP && PARSER)
  {
	if (e->ET)
	{   type_debug(e->ET);
	    if (tybasic(e->ET->Tty) == TYstruct
#if !TX86
 && (e->PEFflags & PEFstrsize)
#endif
	       )
	    	dbg_printf("%d ",e->Enumbytes);
	    WRTYxx(e->ET->Tty);
	}
  }
  else
  {
	if ((e->Eoper == OPstrpar || e->Eoper == OPstrctor || e->Eoper == OPstreq) ||
	    e->Ety == TYstruct)
	    dbg_printf("%d ",e->Enumbytes);
	WRTYxx(e->Ety);
  }
  if (OTunary(e->Eoper))
  {
	if (e->E2)
	    dbg_printf("%p %p\n",e->E1,e->E2);
	else
	    dbg_printf("%p\n",e->E1);
	elem_print(e->E1);
  }
  else if (OTbinary(e->Eoper))
  {
	if (!PARSER && e->Eoper == OPstreq)
		dbg_printf("bytes=%d ",e->Enumbytes);
	dbg_printf("%p %p\n",e->E1,e->E2);
	elem_print(e->E1);
	elem_print(e->E2);
  }
  else
  {
	switch (e->Eoper)
	{
	    case OPrelconst:
		dbg_printf(" %d+&",e->Eoffset);
		dbg_printf(" %s",e->EV.sp.Vsym->Sident);
		break;
	    case OPvar:
		if (e->Eoffset)
		    dbg_printf(" %d+",e->Eoffset);
		dbg_printf(" %s",e->EV.sp.Vsym->Sident);
		break;
	    case OPasm:
	    case OPstring:
	    case OPhstring:
		dbg_printf(" '%s',%d\n",e->EV.ss.Vstring,e->EV.ss.Voffset);
		break;
	    case OPconst:
		tym = tybasic(typemask(e));
	    case_tym:
		switch (tym)
		{   case TYbool:
		    case TYchar:
		    case TYschar:
		    case TYuchar:
			dbg_printf("%d ",e->EV.Vuchar);
			break;
#if TX86
		    case TYsptr:
#if JHANDLE
		    case TYjhandle:
#endif
		    case TYnptr:
		    case TYcptr:
#endif
			if (NPTRSIZE == LONGSIZE)
			    goto L1;
			if (NPTRSIZE == SHORTSIZE)
			    goto L3;
			if (NPTRSIZE == LLONGSIZE)
			    goto L2;
			assert(0);
			break;
		    case TYenum:
			if (PARSER)
			{   tym = e->ET->Tnext->Tty;
			    goto case_tym;
			}
		    case TYint:
		    case TYuint:
		    case TYvoid:	/* in case (void)(1)	*/
#if TX86
			if (tysize[TYint] == LONGSIZE)
			    goto L1;
#endif
		    case TYshort:
		    case TYwchar_t:
		    case TYushort:
		    L3:
#if TX86
			dbg_printf("%hd ",e->EV.Vint);
			break;
#endif
		    case TYlong:
		    case TYulong:
		    case TYdchar:
		    case TYfptr:
#if TX86
		    case TYvptr:
		    case TYhptr:
#endif
		    L1:
			dbg_printf("%ldL ",e->EV.Vlong);
			break;

		    case TYllong:
		    L2:
			dbg_printf("%lldLL ",e->EV.Vllong);
			break;

		    case TYullong:
			dbg_printf("%lluLL ",e->EV.Vullong);
			break;

		    case TYfloat:
			dbg_printf("%gf ",(double)e->EV.Vfloat);
			break;
		    case TYdouble:
		    case TYdouble_alias:
			dbg_printf("%g ",(double)e->EV.Vdouble);
			break;
		    case TYldouble:
#if TARGET_MAC
#if (TARGET_POWERPC)
			if (config.flags & CFGldblisdbl)
			    dbg_printf("%gL ",e->EV.Vdouble);
			else
#endif
#if !DDRT
			    dbg_printf("%LgL ",e->EV.Vldouble);
#else /* DDRT */
			{
		    	    static char buffer[75];
		    	    __g_fmt(buffer, (DD)e->EV.Vldouble);
	    	    	    dbg_printf("%sL", buffer);
			}
#endif /* DDRT */
			break;
		    case TYvptr:
		        dbg_printf("%ldL ",e->EV.Vlong);
			break;
#else
			dbg_printf("%gL ",(double)e->EV.Vldouble);
#endif
			break;

		    case TYifloat:
			dbg_printf("%gfi ", (double)e->EV.Vfloat);
			break;

		    case TYidouble:
			dbg_printf("%gi ", (double)e->EV.Vdouble);
			break;

		    case TYildouble:
			dbg_printf("%gLi ", (double)e->EV.Vldouble);
			break;

		    case TYcfloat:
			dbg_printf("%gf+%gfi ", (double)e->EV.Vcfloat.re, (double)e->EV.Vcfloat.im);
			break;

		    case TYcdouble:
			dbg_printf("%g+%gi ", (double)e->EV.Vcdouble.re, (double)e->EV.Vcdouble.im);
			break;

		    case TYcldouble:
			dbg_printf("%gL+%gLi ", (double)e->EV.Vcldouble.re, (double)e->EV.Vcldouble.im);
			break;

		    case TYident:
			dbg_printf("'%s' ", e->ET->Tident);
			break;

		    default:
			dbg_printf("Invalid type ");
			WRTYxx(typemask(e));
			/*assert(0);*/
		}
		break;
	    default:
		break;
	}
	dbg_printf("\n");
  }
ret:
  nestlevel--;
}

#endif

/**********************************
 * Hydrate an elem.
 */

#if HYDRATE
void el_hydrate(elem **pe)
{
    elem *e;

    if (!isdehydrated(*pe))
	return;

    assert(PARSER);
    e = (elem *) ph_hydrate(pe);
    elem_debug(e);
#ifdef DEBUG
    if (!(e->Eoper < OPMAX))
	dbg_printf("e = x%lx, e->Eoper = %d\n",e,e->Eoper);
#endif
    debug_assert(e->Eoper < OPMAX);
    type_hydrate(&e->ET);
#if TARGET_MAC
#else
    if (configv.addlinenumbers)
    {	filename_translate(&e->Esrcpos);
	srcpos_hydrate(&e->Esrcpos);
    }
#endif
    if (EOP(e))
    {	el_hydrate(&e->E1);
	if (EBIN(e))
	    el_hydrate(&e->E2);
#if SCPP
	else if (e->Eoper == OPctor)
	{   symbol_hydrate(&e->EV.eop.Edtor);
	    symbol_debug(e->EV.eop.Edtor);
	}
#endif
    }
    else
    {
	switch (e->Eoper)
	{   case OPstring:
	    case OPasm:
		ph_hydrate(&e->EV.ss.Vstring);
		break;

	    case OPrelconst:
		//if (tybasic(e->ET->Tty) == TYmemptr)
		    //el_hydrate(&e->EV.sm.ethis);
	    case OPvar:
#if TX86
		symbol_hydrate(&e->EV.sp.Vsym);
#else
		ph_hydrate(&e->EV.sp.Vsym);
#endif
		symbol_debug(e->EV.sp.Vsym);
		break;
	}
    }
}
#endif

/**********************************
 * Dehydrate an elem.
 */

#if DEHYDRATE
void el_dehydrate(elem **pe)
{   elem *e;

    if ((e = *pe) == NULL || isdehydrated(e))
	return;

    assert(PARSER);
    elem_debug(e);
#ifdef DEBUG
    if (!(e->Eoper < OPMAX))
	dbg_printf("e = x%lx, e->Eoper = %d\n",e,e->Eoper);
#endif
    debug_assert(e->Eoper < OPMAX);
    ph_dehydrate(pe);
#if DEBUG_XSYMGEN
    if (xsym_gen && ph_in_head(e))
    	return;
#endif
    type_dehydrate(&e->ET);
#if TX86
    if (configv.addlinenumbers)
	srcpos_dehydrate(&e->Esrcpos);
#endif
    if (EOP(e))
    {	el_dehydrate(&e->E1);
	if (EBIN(e))
	    el_dehydrate(&e->E2);
#if SCPP
	else if (e->Eoper == OPctor)
	    symbol_dehydrate(&e->EV.eop.Edtor);
#endif
    }
    else
    {
	switch (e->Eoper)
	{   case OPstring:
	    case OPasm:
		ph_dehydrate(&e->EV.ss.Vstring);
		break;
	    case OPrelconst:
		//if (tybasic(e->ET->Tty) == TYmemptr)
		    //el_dehydrate(&e->EV.sm.ethis);
	    case OPvar:
#if TX86
		symbol_dehydrate(&e->EV.sp.Vsym);
#else
		ph_dehydrate(&e->EV.sp.Vsym);
#endif
		break;
	}
    }
}
#endif

#endif /* !SPP */
